Multi-protocol bus circuit

ABSTRACT

A multi-protocol bus circuit is provided. The multi-protocol bus circuit includes multiple master circuits each configured to communicate a respective master bus command(s) via a respective one of multiple master buses based on a respective one of multiple master bus protocols, and a slave circuit(s) configured to communicate a slave bus command(s) via a slave bus based on a slave bus protocol that is different from any of the master bus protocols. To enable bidirectional bus communications between the master circuits and the slave circuit(s), the multi-protocol bus circuit further includes a multi-protocol bridge circuit configured to perform a bidirectional conversion between the slave bus protocol and each of the master bus protocols. As a result, it is possible to support bidirectional bus communications based on heterogeneous bus protocols with minimal impact on cost and/or footprint.

FIELD OF DISCLOSURE

The technology of the disclosure relates generally to a hybrid busapparatus incorporating heterogeneous communication buses.

BACKGROUND

Mobile communication devices have become increasingly common in currentsociety. The prevalence of these mobile communication devices is drivenin part by the many functions that are now enabled on such devices.Increased processing capabilities in such devices means that mobilecommunication devices have evolved from being pure communication toolsinto sophisticated mobile multimedia centers that enable enhanced userexperiences.

The redefined user experience requires higher data rates offered bywireless communication technologies, such as Wi-Fi, long-term evolution(LTE), and fifth-generation new-radio (5G-NR). To achieve the higherdata rates in a mobile communication device, a radio frequency (RF)signal(s) may first be modulated by a transceiver circuit(s) based on aselected modulation and coding scheme (MCS) and then amplified by apower amplifier(s) prior to being radiated from an antenna(s). In manywireless communication devices, the power amplifier(s) and theantenna(s) are typically located in an RF front-end (RFFE) circuitcommunicatively coupled to the transceiver circuit(s) via an RFFE busbased on an RFFE protocol as defined in the MIPI® alliance specificationfor radio frequency front-end control interface, version 2.1(hereinafter referred to as “RFFE specification”).

In this regard, FIG. 1 is a schematic diagram of an exemplary RFFE busapparatus 10 as defined in the RFFE specification. The RFFE busapparatus 10 includes an RFFE master 12 coupled to a number of RFFEslaves 14(1)-14(M) over an RFFE bus 16. According to the RFFEspecification, the RFFE bus 16 is a two-wire serial bus that includes adata line 18 and a clock line 20 for communicating a bidirectional datasignal SDATA and a clock signal SCLK, respectively. The RFFE bus 16operates at a first data rate.

However, not all communications require a two-wire serial bus like theRFFE bus 16. In some cases, a single-wire serial bus may be sufficientor even desired for carrying out certain types of communications betweencircuits. In this regard, FIG. 2 is a schematic diagram of an exemplaryconventional hybrid bus apparatus 22 in which a single-wire bus (SuBUS)bridge circuit 24 is configured to bridge communications between theRFFE master 12 in FIG. 1 with one or more SuBUS slaves 26(1)-26(N).Common elements between FIGS. 1 and 2 are shown therein with commonelement numbers and will not be re-described herein.

The SuBUS bridge circuit 24 is coupled to the SuBUS slaves 26(1)-26(N)over a SuBUS 28 having a single data wire 30. Accordingly, the SuBUS 28is configured to operate at a second data rate that can be faster orslower than the first data rate of the RFFE bus 16. The SuBUS bridgecircuit 24 may be coupled to the RFFE master 12 via the RFFE bus 16. Inthis regard, the SuBUS bridge circuit 24 and the SuBUS slaves26(1)-26(N) are also RFFE slaves, such as the RFFE slaves 14(1)-14(M)coupled to the RFFE master 12 in the RFFE bus apparatus 10 of FIG. 1 .

Notably, the SuBUS 28 differs from the RFFE bus 16 in several aspects.First, the RFFE bus 16 includes the data line 18 and the clock line 20,while the SuBUS 28 includes only the single data wire 30. Second, theSuBUS bridge circuit 24 is configured to communicate with the SuBUSslaves 26(1)-26(N) based on SuBUS command sequences, which may becompatible but different from the RFFE command sequences communicatedover the RFFE bus 16. In this regard, the SuBUS bridge circuit 24 mayperform command conversion between the RFFE command sequences and theSuBUS command sequences to facilitate communications between the RFFEbus 16 and the SuBUS 28. Third, the RFFE bus 16 may be configured tooperate at the first data rate and the SuBUS 28 may be configured tooperate at the second data rate, which is different from the first datarate. In this regard, the SuBUS bridge circuit 24 may buffer SuBUS datapayloads prior to communicating over the RFFE bus 16 to help compensatefor a difference between the first data rate and the second data rate.

Besides the power amplifier(s) and the antenna(s), the SuBUS slaves26(1)-26(N) can also include other types of active or passive circuits(e.g., audio circuits) that need to communicate with other types ofmasters via the SuBUS 28. Given that the SuBUS bridge circuit 24 in theconventional hybrid bus apparatus 22 is only capable of bridging theSuBUS slaves 26(1)-26(N) with a single RFFE master 12 based exclusivelyon the RFFE protocol, it may be necessary to employ additional SuBUSbridge circuits to bridge the SuBUS slaves 26(1)-26(N) to additionaltypes of masters. As a result, the conventional hybrid bus apparatus 22may occupy a larger footprint and/or become more expensive.

SUMMARY

Aspects disclosed in the detailed description include a multi-protocolbus circuit. The multi-protocol bus circuit includes multiple mastercircuits each configured to communicate a respective master buscommand(s) via a respective one of multiple master buses based on arespective one of multiple master bus protocols, and a slave circuit(s)configured to communicate a slave bus command(s) via a slave bus basedon a slave bus protocol that is different from any of the master busprotocols. To enable bidirectional bus communications between the mastercircuits and the slave circuit(s), the multi-protocol bus circuitfurther includes a multi-protocol bridge circuit configured to perform abidirectional conversion between the slave bus protocol and each of themaster bus protocols. As a result, it is possible to supportbidirectional bus communications based on heterogeneous bus protocolswith minimal impact on cost and/or footprint.

In one aspect, a multi-protocol bus circuit is provided. Themulti-protocol bus circuit includes multiple master circuits eachcoupled to a respective on of multiple master buses. The multiple mastercircuits are each configured to communicate a respective one or moremaster bus commands based on a respective one of multiple master busprotocols. Each of the master bus protocols is different from at leastanother one of the master bus protocols. The multi-protocol bus circuitalso includes one or more slave circuits each coupled to a slave bus.The slave circuits are each configured to communicate a respective oneor more slave bus commands based on a slave bus protocol different fromany of the master bus protocols. The multi-protocol bus circuit alsoincludes a multi-protocol bridge circuit coupled to the master buses andthe slave bus. The multi-protocol bridge circuit is configured toperform a bidirectional conversion between the slave bus protocol andeach of the master bus protocols.

In another aspect, a multi-protocol bridge circuit is provided. Themulti-protocol bridge circuit includes multiple master bus ports eachcoupled to a respective one of multiple master circuits configured tocommunicate a respective one or more master bus commands via arespective one of multiple master buses based on a respective one ofmultiple master bus protocols. Each of the master bus protocols isdifferent from at least another one of the master bus protocols. Themulti-protocol bridge circuit also includes a slave bus port coupled toone or more slave circuits. The slave circuits are each configured tocommunicate a respective one or more slave bus commands based on a slavebus protocol different from any of the master bus protocols. Themulti-protocol bridge circuit also includes a control circuit. Thecontrol circuit is configured to perform a bidirectional conversionbetween the slave bus protocol and each of the master bus protocols.

Those skilled in the art will appreciate the scope of the disclosure andrealize additional aspects thereof after reading the following detaileddescription in association with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings incorporated in and forming a part of thisspecification illustrate several aspects of the disclosure and, togetherwith the description, serve to explain the principles of the disclosure.

FIG. 1 is a schematic diagram of an exemplary radio frequency front-end(RFFE) bus apparatus as defined in the MIPI® alliance specification forradio frequency (RF) front-end control interface, version 2.1;

FIG. 2 is a schematic diagram of an exemplary conventional hybrid busapparatus in which a single-wire bus (SuBUS) bridge circuit isconfigured to bridge communications between an RFFE master in the RFFEbus apparatus of FIG. 1 with one or more SuBUS slaves; and

FIG. 3 is a schematic diagram of an exemplary multi-protocol hybrid busapparatus configured according to embodiments of the present disclosureto support bidirectional bus communications between multiple mastercircuits and a slave circuit(s) based on heterogeneous bus protocols.

DETAILED DESCRIPTION

The embodiments set forth below represent the necessary information toenable those skilled in the art to practice the embodiments andillustrate the best mode of practicing the embodiments. Upon reading thefollowing description in light of the accompanying drawing figures,those skilled in the art will understand the concepts of the disclosureand will recognize applications of these concepts not particularlyaddressed herein. It should be understood that these concepts andapplications fall within the scope of the disclosure and theaccompanying claims.

It will be understood that, although the terms first, second, etc. maybe used herein to describe various elements, these elements should notbe limited by these terms. These terms are only used to distinguish oneelement from another. For example, a first element could be termed asecond element, and, similarly, a second element could be termed a firstelement, without departing from the scope of the present disclosure. Asused herein, the term “and/or” includes any and all combinations of oneor more of the associated listed items.

It will be understood that when an element such as a layer, region, orsubstrate is referred to as being “on” or extending “onto” anotherelement, it can be directly on or extend directly onto the other elementor intervening elements may also be present. In contrast, when anelement is referred to as being “directly on” or extending “directlyonto” another element, there are no intervening elements present.Likewise, it will be understood that when an element such as a layer,region, or substrate is referred to as being “over” or extending “over”another element, it can be directly over or extend directly over theother element or intervening elements may also be present. In contrast,when an element is referred to as being “directly over” or extending“directly over” another element, there are no intervening elementspresent. It will also be understood that when an element is referred toas being “connected” or “coupled” to another element, it can be directlyconnected or coupled to the other element or intervening elements may bepresent. In contrast, when an element is referred to as being “directlyconnected” or “directly coupled” to another element, there are nointervening elements present.

Relative terms such as “below” or “above” or “upper” or “lower” or“horizontal” or “vertical” may be used herein to describe a relationshipof one element, layer, or region to another element, layer, or region asillustrated in the Figures. It will be understood that these terms andthose discussed above are intended to encompass different orientationsof the device in addition to the orientation depicted in the Figures.

The terminology used herein is for the purpose of describing particularembodiments only and is not intended to be limiting of the disclosure.As used herein, the singular forms “a,” “an,” and “the” are intended toinclude the plural forms as well, unless the context clearly indicatesotherwise. It will be further understood that the terms “comprises,”“comprising,” “includes,” and/or “including” when used herein specifythe presence of stated features, integers, steps, operations, elements,and/or components, but do not preclude the presence or addition of oneor more other features, integers, steps, operations, elements,components, and/or groups thereof.

Unless otherwise defined, all terms (including technical and scientificterms) used herein have the same meaning as commonly understood by oneof ordinary skill in the art to which this disclosure belongs. It willbe further understood that terms used herein should be interpreted ashaving a meaning that is consistent with their meaning in the context ofthis specification and the relevant art and will not be interpreted inan idealized or overly formal sense unless expressly so defined herein.

Aspects disclosed in the detailed description include a multi-protocolbus circuit. The multi-protocol bus circuit includes multiple mastercircuits each configured to communicate a respective master buscommand(s) via a respective one of multiple master buses based on arespective one of multiple master bus protocols, and a slave circuit(s)configured to communicate a slave bus command(s) via a slave bus basedon a slave bus protocol that is different from any of the master busprotocols. To enable bidirectional bus communications between the mastercircuits and the slave circuit(s), the multi-protocol bus circuitfurther includes a multi-protocol bridge circuit configured to perform abidirectional conversion between the slave bus protocol and each of themaster bus protocols. As a result, it is possible to supportbidirectional bus communications based on heterogeneous bus protocolswith minimal impact on cost and/or footprint.

In this regard, FIG. 3 is a schematic diagram of an exemplarymulti-protocol bus circuit 32 configured according to embodiments of thepresent disclosure to support bidirectional bus communications betweenmultiple master circuits 34(1)-34(M) and one or more slave circuits36(1)-36(N) based on heterogeneous bus protocols. Herein, thebidirectional bus communications refer to bus communications originatedfrom any of the master circuits 34(1)-34(M) and destined to any of theslave circuits 36(1)-36(N) (a.k.a. forward communication), and buscommunications originated from any of the slave circuits 36(1)-36(N) anddestined to any of the master circuits 34(1)-34(M) (a.k.a. reversecommunication).

The master circuits 34(1)-34(M) are coupled to multiple master buses38(1)-38(M), respectively. Each of the master circuits 34(1)-34(M) isconfigured to communicate a respective one or more master bus commands40(1)-40(K) based on a respective one of multiple master bus protocolsP_(M1)-P_(MM). In some embodiments, all of the master bus protocolsP_(M1)-P_(MM) are different bus protocols. In this regard, each of themaster bus protocols P_(M1)-P_(MM) is different from any other one ofthe master bus protocols P_(M1)-P_(MM). In some other embodiments, onlya subset of the master bus protocols P_(M1)-P_(MM) are different busprotocols. In this regard, each of the master bus protocolsP_(M1)-P_(MM) is different from at least another one of the master busprotocols P_(M1)-P_(MM).

The slave circuits 36(1)-36(N) are each coupled to a slave bus 42 andconfigured to communicate a respective one or more slave bus commands44(1)-44(L) based on a slave bus protocol P_(S) that is different fromany of the master bus protocols P_(M1)-P_(MM). In a non-limitingexample, the slave bus 42 is a single-wire bus (SuBUS) that isfunctionally equivalent to the SuBUS 28 in FIG. 2 . Accordingly, each ofthe slave circuits 36(1)-36(N) can be functionally equivalent to theSuBUS slaves 26(1)-26(N) in FIG. 2 .

To enable the bidirectional bus communications based on theheterogeneous bus protocols, the multi-protocol bus circuit is furtherconfigured to include a multi-protocol bridge circuit 46. In anembodiment, the multi-protocol bridge circuit 46 includes multiplemaster ports 48(1)-48(M), each coupled to a respective one of the masterbuses 38(1)-38(M). The multi-protocol bridge circuit 46 also includes aslave bus port 50 coupled to the slave bus 42. As discussed in furtherdetail below, the multi-protocol bridge circuit 46 can be configured toperform a bidirectional conversion between the slave bus protocol P_(S)and each of the master bus protocols P_(M1)-P_(MM). Herein, thebidirectional conversion refers to converting the master bus commands40(1)-40(K) from any of the master bus protocols P_(M1)-P_(MM) into theslave bus commands 44(1)-44(L) in accordance with the slave bus protocolP_(S), and vice versa. By bridging the master circuits 34(1)-34(M) withthe slave circuits 36(1)-36(N) using the multi-protocol bridge circuit46, it is possible to support bidirectional bus communications based onheterogeneous bus protocols with minimal cost and/or footprint impact onthe multi-protocol bus circuit 32.

In an embodiment, the multi-protocol bridge circuit 46 includes acontrol circuit 52, which can be a field-programmable gate array (FPGA)or an application-specific integrated circuit (ASIC), as an example. Toenable the forward communication, the control circuit 52 can beconfigured to receive the respective master bus commands 40(1)-40(K)from any of the master circuits 34(1)-34(M) via a respective one of themaster ports 48(1)-48(M). Notably, the respective master bus commands40(1)-40(K) may be destined to any of the slave circuits 36(1)-36(N) orto the multi-protocol bridge circuit 46 itself. In this regard, thecontrol circuit 52 may be configured to first determine whether therespective master bus commands 40(1)-40(K) are destined to at least oneof the slave circuits 36(1)-36(N). If the control circuit 52 determinesthat the respective master bus commands 40(1)-40(K) are indeed destinedto any of the slave circuits 36(1)-36(N), the control circuit 52 willthen convert the respective master bus commands 40(1)-40(K) into therespective slave bus commands 44(1)-44(L) and provide the respectiveslave bus commands 44(1)-44(L) to any of the slave circuits 36(1)-36(N)to which the respective master bus commands 40(1)-40(K) are destined.

To enable the reverse communication, the control circuit 52 isconfigured to receive the respective slave bus commands 44(1)-44(L) fromany of the one or more slave circuits 36(1)-36(N) via the slave bus port50. Notably, the respective slave bus commands 44(1)-44(L) may bedestined to any of the master circuits 34(1)-34(M) or to themulti-protocol bridge circuit 46 itself. In this regard, the controlcircuit 52 may be configured to first determine whether the respectiveslave bus commands 44(1)-44(L) are destined to at least one of themaster circuits 34(1)-34(M). If the control circuit 52 determines thatthe respective slave bus commands 44(1)-44(L) are indeed destined to anyof the master circuits 34(1)-34(M), the control circuit 52 will thenconvert the respective slave bus commands 44(1)-44(L) into therespective master bus commands 40(1)-40(M) and provide the respectivemaster bus commands 40(1)-40(M) to any of the master circuits34(1)-34(N) to which the respective slave bus commands 44(1)-44(L) aredestined.

In an embodiment, the control circuit 52 can include at least oneencoder-decoder circuit 54 (denoted as “CODEC”). Specifically, theencoder-decoder circuit 54 can be configured to convert the respectivemaster bus commands 40(1)-40(M) into the respective slave bus commands44(1)-44(L) in the forward communication, and to convert the respectiveslave bus commands 44(1)-44(L) into the respective master bus commands40(1)-40K) in the reverse communication.

In an embodiment, the multi-protocol bridge circuit 46 maysimultaneously receive the respective master bus commands 40(1)-40(M)from more than one of the master circuits 34(1)-34(M). In this regard,upon converting the respective master bus commands 40(1)-40(M) receivedfrom each of the master circuits 34(1)-34(M) into the respective slavebus commands 44(1)-44(L), the control circuit 52 needs to determine anorder for providing the respective slave bus commands 44(1)-44(L) tosome or all of the slave circuits 36(1)-36(N).

For example, the control circuit 52 can provide the respective slave buscommands 44(1)-44(L), which are converted from the respective master buscommands 40(1)-40(M) received simultaneously from more than one of themaster circuits 34(1)-34(M), to any of the slave circuits 36(1)-36(N)based on a predefined priority of the master circuits 34(1)-34(M). Inthis regard, the respective slave bus commands 44(1)-44(L) convertedfrom the respective master bus commands 40(1)-40(M) received from ahigher priority one of the master circuits 34(1)-34(M) will be sent tothe slave bus port 50 before the respective slave bus commands44(1)-44(L) converted from the respective master bus commands40(1)-40(M) are received from a lower priority one of the mastercircuits 34(1)-34(M).

In a non-limiting example, the control circuit 52 can include a databuffer 56 that functions as a first-in first-out (FIFO) queue. In thisregard, the control circuit 52 may be configured to enqueue therespective slave bus commands 44(1)-44(L) based on the predefinedpriority of the master circuits 34(1)-34(M). In other words, the controlcircuit 52 will enqueue the respective slave bus commands 44(1)-44(L)that are converted from the respective master bus commands 40(1)-40(M)received from the higher priority one of the master circuits 34(1)-34(M)in the data buffer 56 before enqueuing the respective slave bus commands44(1)-44(L) that are converted from the respective master bus commands40(1)-40(M) received from the lower priority one of the master circuits34(1)-34(M).

In an embodiment, the data buffer 56 may be utilized only for theforward communication. As for the reverse communication, the respectiveslave bus commands 44(1)-44(L) received from any of the slave circuits36(1)-36(N) are directly routed to the encoder-decoder circuit 54 fromthe slave bus port 50. Accordingly, the encoder-decoder circuit 54 isconfigured to convert the respective slave bus commands 44(1)-44(L)destined to any of the master circuits 34(1)-34(M) on a first come firstserve basis.

In an embodiment, the multi-protocol bridge circuit 46 can include astorage circuit 58 (denoted as “REGMAP”), which can be a register bank,or a flash storage circuit, as an example. The storage circuit 58 may beprogrammed to store the predefined priority among the master circuits34(1)-34(M).

As previously mentioned, the respective master bus commands 40(1)-40(K)originated from any of the master circuits 34(1)-34(M) can be destinedto the multi-protocol bridge circuit 46, as opposed to any of the slavecircuits 36(1)-36(N). In this regard, the respective master bus commands40(1)-40(K), which are originated from any of the master circuits34(1)-34(M) and destined to the multi-protocol bridge circuit 46, may beutilized to program (dynamically or statically) the predefined priorityin the storage circuit 58.

In an embodiment, each of the master circuits 34(1)-34(M) may beconfigured to communicate the respective master bus commands 40(1)-40(K)by asserting a respective one of multiple master bus voltagesV_(M1)-V_(MM) on the respective one of the master buses 38(1)-38(M). Incontrast, each of the slave circuits 36(1)-36(N) is configured tocommunicate the respective slave bus commands 44(1)-44(L) based on aslave bus voltage V_(S) that is different from at least one of themaster bus voltages V_(M1)-V_(MM). Notably, any mismatch between themaster bus voltages V_(M1)-V_(MM) and the slave bus voltage V_(S) cancause potential damage to the slave circuits 36(1)-36(N), particularlywhen the slave bus voltage V_(S) is lower than any mismatched master busvoltage among the master bus voltages V_(M1)-V_(MM).

In this regard, the multi-protocol bridge circuit 46 can be furtherconfigured to perform a bidirectional voltage conversion between theslave bus voltage V_(S) and any of the master bus voltagesV_(M1)-V_(MM). In a non-limiting example, the multi-protocol bridgecircuit 46 can further include multiple master bus interface circuits60(1)-60(M), each coupled to a respective one of the master ports48(1)-48(M). More specifically, each of the master bus interfacecircuits 60(1)-60(M) can include a respective voltage conversion circuit62, which can be a capacitor-based or an inductor-based buck-boostconverter, or a level shifter, as an example, for carrying out thebidirectional voltage conversion between the slave bus voltage V_(S) andany of the master bus voltage V_(M1)-V_(MM).

As a non-limiting example, the multi-protocol bridge circuit 46 caninclude a radio-frequency front-end (RFFE) master circuit (e.g., themaster circuit 34(1)) and an inter-integrated circuit (I2C) mastercircuit (e.g., the master circuit 34(M)). In this regard, the RFFEmaster circuit 34(1) is configured to communicate one or more RFFE buscommands 40(1)-40(K) over the RFFE bus 38(1) based on an RFFE busprotocol and by asserting a respective one of the master bus voltageV_(M1)-V_(MM) on the RFFE bus 38(1), and the I2C master circuit 34(M) isconfigured to communicate one or more I2C bus commands 40(1)-40(K) overthe I2C bus 38(M) based on a I2C bus protocol and by asserting arespective one of the master bus voltage V_(M1)-V_(MM) on the I2C bus38(M). Each of the slave circuits 36(1)-36(N), on the other hand, is aSuBUS slave circuit configured to communicate the respective SuBUS slavebus commands 44(1)-44(N) over the SuBUS 42 based on the SuBUS protocol.

Accordingly, the multi-protocol bridge circuit 46 is configured toperform the bidirectional conversion between the RFFE bus protocol, theI2C bus protocol, and the SuBUS bus protocol. In addition, themulti-protocol bridge circuit 46 may also perform the bidirectionalvoltage conversion should there be a mismatch between the RFFE masterbus voltage V_(M1), the I2C master bus voltage V_(MM), and the SuBUSslave bus voltage V_(S).

The multi-protocol bridge circuit 46 can further include a second RFFEmaster circuit (e.g., the master circuit 34(2)), which is configured tocommunicate a respective one or more RFFE bus commands 40(1)-40(K) overa respective one of the master buses (e.g., the master bus 38(2)) basedon the RFFE bus protocol. However, the second RFFE master circuit isconfigured to assert a different master bus voltage from the respectivemaster bus voltage asserted by the RFFE master circuit 38(1).

Those skilled in the art will recognize improvements and modificationsto the embodiments of the present disclosure. All such improvements andmodifications are considered within the scope of the concepts disclosedherein and the claims that follow.

What is claimed is:
 1. A multi-protocol bus circuit comprising: aplurality of master circuits each coupled to a respective one of aplurality of master buses and configured to communicate a respective oneor more master bus commands based on a respective one of a plurality ofmaster bus protocols, wherein each of the plurality of master busprotocols is different from at least another one of the plurality ofmaster bus protocols; one or more slave circuits each coupled to a slavebus and configured to communicate a respective one or more slave buscommands based on a slave bus protocol different from any of theplurality of master bus protocols; and a multi-protocol bridge circuitcoupled to the plurality of master buses and the slave bus andconfigured to perform a bidirectional conversion between the slave busprotocol and each of the plurality of master bus protocols.
 2. Themulti-protocol bus circuit of claim 1, wherein: the plurality of mastercircuits comprises: a radio-frequency front-end (RFFE) master circuitcoupled to an RFFE bus and configured to communicate one or more RFFEbus commands based on an RFFE bus protocol; an inter-integrated circuit(I2C) master circuit coupled to a I2C bus and configured to communicateone or more I2C bus commands based on a I2C bus protocol; the one ormore slave circuits comprise one or more single-wire bus (SuBUS) slavecircuits each coupled to an SuBUS and configured to communicate arespective one or more SuBUS commands based on an SuBUS protocol; andthe multi-protocol bridge circuit is coupled to the RFFE bus, the I2Cbus, and the SuBUS and configured to perform the bidirectionalconversion between the SuBUS protocol and each of the RFFE bus protocoland the I2C bus protocol.
 3. The multi-protocol bus circuit of claim 1,wherein the multi-protocol bridge circuit is further configured to:receive the respective one or more master bus commands from therespective one of the plurality of master circuits via the respectiveone of the plurality of master buses; determine that the respective oneor more master bus commands are destined to at least one of the one ormore slave circuits; convert the respective one or more master buscommands into the respective one or more slave bus commands of the atleast one of the one or more slave circuits; and provide the respectiveone or more slave bus commands to the at least one of the one or moreslave circuits.
 4. The multi-protocol bus circuit of claim 3, whereinthe multi-protocol bridge circuit is further configured to: receive therespective one or more slave bus commands from the at least one of theone or more slave circuits; convert the respective one or more slave buscommands into the respective one or more master bus commands of the atleast one of the plurality of master circuits; and provide therespective one or more master bus commands to the at least one of theplurality of master circuits.
 5. The multi-protocol bus circuit of claim4, wherein the multi-protocol bridge circuit comprises at least oneencoder-decoder circuit configured to: convert the respective one ormore master bus commands into the respective one or more slave buscommands of the at least one of the one or more slave circuits; andconvert the respective one or more slave bus commands into therespective one or more master bus commands of the at least one of theplurality of master circuits.
 6. The multi-protocol bus circuit of claim1, wherein the multi-protocol bridge circuit is further configured to:receive concurrently the respective one or more master bus commands fromeach of the plurality of master circuits; determine that the respectiveone or more master bus commands received from the each of the pluralityof master circuits are destined to the at least one of the one or moreslave circuits; convert the respective one or more master bus commandsreceived from the each of the plurality of master circuits into therespective one or more slave bus commands; and provide the respectiveone or more slave bus commands to the at least one of the one or moreslave circuits based on a predefined priority of the plurality of mastercircuits.
 7. The multi-protocol bus circuit of claim 6, furthercomprising a data buffer coupled to the slave bus, wherein themulti-protocol bridge circuit is further configured to enqueue therespective one or more slave bus commands destined to the at least oneof the one or more slave circuits in the data buffer based on thepredefined priority of the plurality of master circuits.
 8. Themulti-protocol bus circuit of claim 6, wherein the multi-protocol bridgecircuit further comprises a storage circuit configured to store thepredefined priority of the plurality of master circuits.
 9. Themulti-protocol bus circuit of claim 8, wherein the multi-protocol bridgecircuit is further configured to: receive the respective one or moremaster bus commands from a respective one of the plurality of mastercircuits via the respective one of the plurality of master buses;determine that the respective one or more master bus commands aredestined to the multi-protocol bridge circuit; and update the predefinedpriority stored in the storage circuit based on the respective one ormore master bus commands.
 10. The multi-protocol bus circuit of claim 1,wherein: each of the plurality of master circuits is further configuredto communicate the respective one or more master bus commands byasserting a respective one of a plurality of master bus voltages on therespective one of the plurality of master buses; and the one or moreslave circuits are each configured to communicate the respective one ormore slave bus commands based on a slave bus voltage different from atleast one of the plurality of master bus voltages.
 11. Themulti-protocol bus circuit of claim 10, wherein the multi-protocolbridge circuit is further configured to: determine that the slave busvoltage is different from the at least one of the plurality of masterbus voltages; and perform bidirectional voltage conversion between theslave bus voltage and the at least one of the plurality of master busvoltages.
 12. The multi-protocol bus circuit of claim 11, wherein themulti-protocol bridge circuit further comprises a plurality of masterbus interface circuits each coupled to a respective one of the pluralityof master circuits, and at least one of the plurality of master businterface circuits is configured to perform the bidirectional voltageconversion between the slave bus voltage and the at least one of theplurality of master bus voltages.
 13. The multi-protocol bus circuit ofclaim 11, wherein at least two of the plurality of master circuits areeach configured to communicate the respective one or more master buscommands based on an identical one of the plurality of master busprotocols and by asserting a different one of the plurality of masterbus voltages on the respective one of the plurality of master buses. 14.A multi-protocol bridge circuit comprising: a plurality of master busports each coupled to a respective one of a plurality of master circuitsconfigured to communicate a respective one or more master bus commandsvia a respective one of a plurality of master buses based on arespective one of a plurality of master bus protocols, wherein each ofthe plurality of master bus protocols is different from at least anotherone of the plurality of master bus protocols; a slave bus port coupledto one or more slave circuits each configured to communicate arespective one or more slave bus commands based on a slave bus protocoldifferent from any of the plurality of master bus protocols; and acontrol circuit configured to perform a bidirectional conversion betweenthe slave bus protocol and each of the plurality of master busprotocols.
 15. The multi-protocol bridge circuit of claim 14, whereinthe control circuit is further configured to: receive the respective oneor more master bus commands via the respective one of the plurality ofmaster bus ports; determine that the respective one or more master buscommands are destined to at least one of the one or more slave circuits;convert the respective one or more master bus commands into therespective one or more slave bus commands; and provide the respectiveone or more slave bus commands to the slave bus port.
 16. Themulti-protocol bridge circuit of claim 15, wherein the control circuitis further configured to: receive the respective one or more slave buscommands via the slave bus port; convert the respective one or moreslave bus commands into the respective one or more master bus commands;and provide the respective one or more master bus commands to at leastone of the plurality of master bus ports.
 17. The multi-protocol bridgecircuit of claim 16, wherein the control circuit comprises at least oneencoder-decoder circuit configured to: convert the respective one ormore master bus commands into the respective one or more slave buscommands; and convert the respective one or more slave bus commands intothe respective one or more master bus commands.
 18. The multi-protocolbridge circuit of claim 14, wherein the control circuit is furtherconfigured to: receive concurrently the respective one or more masterbus commands via each of the plurality of master bus ports; determinethat the respective one or more master bus commands are destined to atleast one of the one or more slave circuits; convert the respective oneor more master bus commands received via the each of the plurality ofmaster bus ports into the respective one or more slave bus commands; andprovide the respective one or more slave bus commands to the slave busport based on a predefined priority of the plurality of master circuits.19. The multi-protocol bridge circuit of claim 18, wherein the controlcircuit further comprises a data buffer coupled to the slave bus port,wherein the control circuit is further configured to enqueue therespective one or more slave bus commands destined to the at least oneof the one or more slave circuits in the data buffer based on thepredefined priority of the plurality of master circuits.
 20. Themulti-protocol bridge circuit of claim 14, wherein: each of theplurality of master circuits is further configured to communicate therespective one or more master bus commands by asserting a respective oneof a plurality of master bus voltages on the respective one of theplurality of master buses; and the one or more slave circuits are eachconfigured to communicate the respective one or more slave bus commandsbased on a slave bus voltage different from at least one of theplurality of master bus voltages.